SU1404204A2 - Milling cutter - Google Patents

Abstract

The invention relates to the design of metal-cutting tools and can be used in research of the cutting process. The purpose of the invention is to expand the scope of application of the structure by enabling research of the cutting process. The milling cutter consists of a housing 1, in the openings of which thin-walled bushings 2 and cutting inserts 3 are installed. Thin-walled bushings form closed cavities 4 with openings of the housing filled with an elastic medium, for example, a hydroplast. In this medium, transducers are installed that do not touch the surfaces housing holes and sleeves. Sample 7 serves to create a preliminary volume-stressed state of an elastic medium. 2 Il. (L

Description

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The invention relates to the design of 1DING metal-cutting tools, can be used in the research institute of the cutting process and is an improvement of the invention according to the author. St. No. 1214343.

The purpose of the invention is to expand the application of the cutter by providing the possibility of conducting research on the cutting process.

FIG. 1 shows the incisor uzep cutter, section; in FIG. 2, section A-A in FIG. one.

The milling cutter consists of the body 1, in the opening of which there are thin-walled bushes 2 and cutting inserts 3 The thin-walled bushes 2 form, with housing openings, closed cavities 4 filled with an elastic medium, such as hydroplast. In the elastic medium, sensors are located; The applicants 5, which are sensitive elements and do not touch the thin-walled sleeve 2 and the cutter body 1. Connecting wires 6 is guided through the housing of the cutter 1. Tube .7 serves to create a preliminary volume-stressed state in transducer sensors 5, Communication of sensors with recording devices, and devices outside the machine, using known techniques. Thus, the proposed mill has a torque unit, which does not change its dimensions, making it compact.

The assembly of the damping assembly is molded from the known assembly in that in the cavity 4 between the thin-walled sleeve 2 and the housing 1 the sensors-preamers 5 are placed without contact and with the indicated elements 1 and 2, and then fill the cavity with an elastic medium, using the elastic property Liquid as a fluid to fill any spaces.

The cutter works as follows

For calibration of the milling cutter, the transducers 5 are connected via wires 6 to

recording equipment, such as a strain amplifier and display devices. The plug 7 creates a volume-stressed state in an elastic medium, i.e. tighten the cork until they start to show the devices. The quality of the creation of a volume-stressed state is verified by the fact that when a load is applied in Ojl. 0.2 N to the cutting insert 3, the instruments do not register it. By changing the plug 7 to the volume-stressed state, it is possible to change the sensitivity threshold of the transducer-sensors 5. Depending on the type of calibration, you can examine the cutting forces, the limit of the performance of a thin-walled sleeve (t, e, determine the value of the force inside and outside the elastic deformations), amplitude and frequency of oscillations perceived or generated by the cutting tool.

On the proposed cutter, it is possible to carry out research-software of many dynamic parameters, to establish their dependence on the geometrical parameters of the cutting inserts. With this, on the proposed construction of the dynamometer assembly it is possible to investigate the relative influence of any geometrical parameters and shapes of the cutting plates as at. The cylindrical insert can be fixed by known methods to fix the cutting plates of taobaya shape, geometry, and physicomechanical properties.

Claims (1)

Invention Formula Mill on auth. St. No. 1214343, which is related to the fact that, in order to expand the field of application of the structure by providing the possibility of carrying out studies of the cutting process, the cutter is equipped with transducers installed inside the three elastic elements without contact with the surfaces of the body openings and thin-walled bushings. FIG. 2